AI Article Synopsis
- Most animal species are cold-blooded and must maintain neuron function despite temperature changes; a study focused on how temperature affects the rhythmic firing of neurons in the crab's stomatogastric ganglion.
- The pyloric rhythm involves three types of neurons (PD, LP, and PY) that fire in a specific order; while the rhythm's frequency increased significantly with temperature, the phase relationships among the neurons remained stable, indicating effective temperature compensation.
- Computational models showed varying effects of temperature on neuronal firing, suggesting that while there's evolutionary pressure on the properties of neurons, the underlying mechanisms for phase stability are critical for adaptive function across different temperatures.
Article Abstract
Most animal species are cold-blooded, and their neuronal circuits must maintain function despite environmental temperature fluctuations. The central pattern generating circuits that produce rhythmic motor patterns depend on the orderly activation of circuit neurons. We describe the effects of temperature on the pyloric rhythm of the stomatogastric ganglion of the crab, Cancer borealis. The pyloric rhythm is a triphasic motor pattern in which the Pyloric Dilator (PD), Lateral Pyloric (LP), and Pyloric (PY) neurons fire in a repeating sequence. While the frequency of the pyloric rhythm increased about 4-fold (Q(10) approximately 2.3) as the temperature was shifted from 7 degrees C to 23 degrees C, the phase relationships of the PD, LP, and PY neurons showed almost perfect temperature compensation. The Q(10)'s of the input conductance, synaptic currents, transient outward current (I(A)), and the hyperpolarization-activated inward current (I(h)), all of which help determine the phase of LP neuron activity, ranged from 1.8 to 4. We studied the effects of temperature in >1,000 computational models (with different sets of maximal conductances) of a bursting neuron and the LP neuron. Many bursting models failed to monotonically increase in frequency as temperature increased. Temperature compensation of LP neuron phase was facilitated when model neurons' currents had Q(10)'s close to 2. Together, these data indicate that although diverse sets of maximal conductances may be found in identified neurons across animals, there may be strong evolutionary pressure to restrict the Q(10)'s of the processes that contribute to temperature compensation of neuronal circuits.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC2930868 | PMC |
| http://dx.doi.org/10.1371/journal.pbio.1000469 | DOI Listing |
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